Dme with automatic search velocity control



March 8, 1966 R. P. cRow DME WITH AUTOMATIC SEARCH VELOCITY CONTROL 8 Sheets-Sheet 1 Filed Nov. l2, 1965 March 8, 1966 R. P. cRow 3,239,835

DME WITH AUTOMATIC SEARCH VELOCITY CONTROL Filed Nov. l2, 1963 8 Sheets-Sheet 2 FE' 0 2l Z670 f//WE l 4006 c s ff/- l 5 4) /7 I zfiacfwsm/fz l [l] iff: ri/ifaus y (C) M100/ 4me Inf/665A w55 K [D] rfAA/.s'M/rfff I /fvrfoAr/wv I a I "5 *l usen I @AA/.15,500,050 (E) .05000547 .f//0f0 l i] l I i l g a l I r I l l ESOZV- 70665? i 1 l' I Affe/wey March 8, 1966 R. P. CROW DME WITH AUTOMATIC SEARCH VELOCITY CONTROL 8 Sheets-Sheet 5 Filed Nov. 12, 1965 March 8, 1966 R. P. CROW DME WITH AUTOMATIC SEARCH VELOCITY CONTROL 8 Sheets-Sheet 4.

Filed NOV.. l2, 1963 'TqTOR Waar-,er Z7 (Paw Ada/w60 WSWS@ March 8, 1966 R. P. CROW DME WITH AUTOMATIC SEARCH VELOCITY CONTROL Filed Nov. l2, 1963 8 Sheets-Sheet 5 March 8, 1966 R. P. cRow 3,239,835

DME WITH AUTOMATIC SEARCH VELOCITY CONTROL INVENTOR. 7055er 160W R. P. CROW DME WITH AUTOMATIC SEARCH VELOCITY CONTROL V Filed NOV. l2, 1963 March 8, 1966 8 Sheets-Sheet 7 March 8, 1966 R. P. cRow DME WITH AUTOMATIC SEARCH VELOCITY CONTROL 8 Sheets-Sheet 8 Filed Nov. 12, 1963 ifm/wed United States Patent O 3,239,835 p p DME WITH AUTOMATIC SEARCH VELOCITY CONTROL Robert l?. Crow, Los Angeles, Calif., assignor to Radio Corporation of America, a corporation of Delaware Filed Nov. 12, 1963, ser. No. 322,858 9 Claims. (Cl. 343-7.3)

My invention relates to improved distance measuring equipment (DME), and particularly Ito such equipment provided with an automatic search velocity control.

DME is airborne radar equipment of the pulse type which interrogates a selected ground beacon or transponder to initiate a reply. The DME receives the reply from the beacon and gives the pilot a reading of the distance from the aircraft to the ground beacon. The DME automatically searches in range by means of a rang'e gate, and then locks in to automatic track-in-range upon reception of several reply pulses that are coincident in time with the range gate, providing the received reply pulses are of suiicient strength.

An object of the invention is to provide improved distance measuring equipment.

A further object of the invention is to provide improved distance measuring equipment having automatic Search velocity control.

A further object of the invention is to provide an improved pulse radar system of the type having yautomatic search-i-n-range and having means for prolonging the life of the electromechanical elements of the ranging portion of the system.

A further object of the invention is vto provide a means whereby failure of any portion of the search velocity control system will not prevent accomplishment of the basic function of the DME, i.e., measurement of distance.

The present invention is concerned, in its preferred embodiment, with the fea-ture of slowing down the automatic search portion of the DME when the received pulses from .the ground station `are not strong enough to make the DME lock in, or lock in reliably. Under these conditions, in the absence of a search veloci-ty or a standby control, the DME continuously searches very rapidly in range until the aircraft gets closer to the selected beacon where the received pulses are stronger.

An advantage of the present invention is that the automatic search part of the DME will have longer life because, in the embodiments herein described, it will be held in slow drive by the automatic search velocity control during times that it would otherwise be in fast drive without providing any useful result. The present invention is particularly important for use in DME having an extremely fast search rate. In the DME described hereinafter, and in which the present invention is incorporated, the system has an extremely fast search-in-range and locks in to automatic track-in-range having a tracking rate which is very slow as compared with the extremely fast search rate. In the specific DME to be described, the search rate is 40 miles per second, and the tracking rate is anywhere from. to 2500 miles per hour (i.e., from 0.00 to 0.7 miles per second) depending upon the speed of the aircraft carrying the DM-E and the relative direction of the ground station. In this example, Ithe DME can search through the entire operating range of 200 miles in tive seconds. Thus, it is possible for the DME Vto lock on to a selected ground station very rapidly and give the range to that station.

In operation, the DME with automatic search velocity control always has its receiver .and decoder in operation (a decoder being included in the DME since the reply pulses are coded). The specific example of the present invention that will be described is designed for use with ground beacons which are always transmitting, whether or not they are being interrogated. Such beacons are, for example, the TACAN ground beacons which operate on the constant-duty-cycle principle. In the absence of interrogation these ground beacons are internally triggered at a random rate. As aircraft come within range of a beacon and the number of interrogations increases, some of the internally triggered pulses are replaced by replies to the interrogations. It will be understood that a particular DME can lock in on a received pulse only if that pulse is in replay to its own interrogation and, therefore, synchronous with it. Y

It may be noted that a TACAN ground beacon constantly transmits about 2700 pairs of pulses per second (each pair having a 12 microsecond spacing) as a result of the internal noise triggering and the interrogation by aircraft. In addition, azimuth reference bursts bring the total of pulse pairs transmitted per second to about 3600.

In one example of the invention, the decoder loutput of the DME is supplied to search velocity control circuitry which includes a threshold circuit. The output of the threshold circut controls a relay, for example, for slowing down the automatic search. If the aircraft is approaching the selected ground beacon from a distance to the beacon that is outside the beacons working range, the pulses received from the beacon will be too weak to pass through the threshold circuit whereby the relay will be in position to hold the automatic search portion of the DME in slow drive.

When the aircraft carrying the DME gets close enough to the ground beacon so that the ground beacons transmitted signal is strong enough so that the DME can lock in on it reliably, the DME receiver passes the ground station signal through the threshold circuit, and the relay is actuated to throw the automatic search into fast drive.

As will be described later in more detail, the DME has four modes of operation which are: (1) automatic trackin-range, (2) proportional memory, (3) automatic searchin-range, and (4) acquisition. From acquisition the DME goes to automatic track-in-range, or back to automatic search (search-iu-range). To explain these modes briefly, the DME is in mode 1 (automatic track) when `a sufficiently strong reply signal is being received and the DME is locked in and indicating range; it is in mode 2 (proportional memory) for a period up to possibly ten seconds in response to loss or fading of the -reply signals and is still indicating range, it goes into mode 3 (automatic search) if the fading or loss of reply signals lasts 4longer than the proportional memory period or upon switching to a new channel; it goes into mode 4 (acquisition) upon return of strong reply pulses, and unless they fade again promptly, it next returns to mode 1.

:In the DME herein described, the range motor is driven by the output of a single servo channel, and the range motor drives ranging units a (distance potentiometer and a resolver, in this example) through gearing and a clutchbrake mechanism. During modes (1), (2) and (4) (see above) the clutch is made to engage so that the drive is through gears that cause the ranging units to be driven comparatively slowly by the range motor. vDuring the search mode (mode 3) the clutch is disengaged and the brake is on so that `the range motor drives through gearing having a gear ratio such that the -ranging units are driven very rapidly.

As the DME switches from one mode of operation to the other, the proper signals are applied to the input of the single servo channel as will be described in detail in the following description. At this time it is suicient to note that during automatic track-in-range (mode 1), the range error signal is applied to the servo channel input,

and the clutch-brake is activated for slow drive of the ranging units; and that `during automatic search-in-range (mode 3), a search voltage is applied to the servo channel input, and the clutch-brake is activated for fast drive of the ranging units.

Two specific embodiments of the invention will be described by way of example. A detailed description of these embodiments is given under the heading Search Velocity Control Circuit, appearing in the latter portion of the specification. In one embodiment, the search velocity control circuit, in the absence of sufficiently strong reply signals, holds a clutch control lead open so that control current cannot pass through it to shift the gearing to the fast search drive condition. Therefore, while the DME is outside the working range of the ground beacon being interrogated and is searching in range, this searching in range occurs at the comparatively slow rate provided by the slow servo drive, and not at the fast rate provided by the fast servo drive employed in the serach mode when the DME is within the working range of the ground beacon.

In another embodiment of the invention, the search velocity circuit, in the absence of sufficiently strong received signals, reduces the search voltage to a low value so that this low voltage (which is applied to the servo channel input circuit) causes the servo to drive the ranging units at a slow rate. Thus, the search-in-range portion of the DME is not driven at the fast rate until the DME is close to or within the working range of the ground beacon.

The invention will be described in detail With reference to the accompanying drawing in which:

FIG. 1 is a block diagram of one embodiment of the invention;

FIG. 2 is a range timing diagram for the apparatus of FIG. 1;

FIG. 3 is a schematic and block diagram of the module 1A17 of FIG. 1;

FIG. 4 is a schematic and block diagram of the module 1A12 of FIG. 1;

FIG. 5 is a schematic diagram of the module 1A11 of FIG. l;

FIG. 6 is a schematic diagram of the clutch-brake and gearing through which the range motor (FIG. 1) drives the ranging units;

FIG. 7 is a schematic diagram illustrating the differential unit incorporated in the gearing shown in FIG. 6;

FIG. 8 is a schematic diagram of the search velocity `control circuit shown as a block in FIG. 1; and

FIG. 9 is a schematic diagram illustrating a second embodiment of the invention.

In the several figures like parts are indicated by similar reference characters.

In order to understand the automatic search velocity icontrol, the DME should first be understood. Tthe DME which will now be described is often referred to as DMET (distance measuring equipment, TACAN). It has assigned to it 126 transmitting channels and 126 receiving channels which are frequency separated. No specific description of the apparatus providing the separate channels is required because it is known.

FIG. 1 is a block diagram of `a DME embodying the present invention. The DME comprises a radio transmitter 10 comprising amplifiers to which a selected carrier Wave is supplied from a frequency synthesizer 11. The desired carrier wave is selected by a suitable channel selector 12. The transmitter is coupled through a lowpass filter 13 to an antenna 14 which functions as both a transmitting and a receiving antenna. The low-pass filter 13 prevents the transmission of harmonics of the transmitter frequency. It also prevents possible spurious receiver responses at frequencies, for example, where the preselector has additional pass bands. The transmitter is modulated by periodically recurring pairs of codespaced pulses supplied from a modulator 16 for interrogating the selected ground beacon.

Reply pulses from the ground beacon are received by antenna 14 and passed through the filter 13 to a preselector 17 which is tuned to receive reply pulses on the transmitting channel of the selected ground station. As indicated by the dotted lines, when the transmitter 10 i-s tuned to interrogate the selected ground station, the preselector is simultaneously tuned to the transmitting frequency of that ground station. The reply signal is passed from perselector 17 to a radio receiver 18. The demodulated reply signal appears at the output of receiver 18 as periodically recurring pairs of video pulses, there being a pair of reply pulses in response to each pair of interrogating pulses. The video pulses from receiver 18 are applied to a decoder 19 which decodes the pairs of pulses to produce a single pulse for each pair of applied pulses.

Range timing circuit Reference is now made to the range timing circuit which comprises, in this example, a crystal controlled oscillator 21 operating at 4046 cycles per second, and which supplies a sine wave signal 2A of constant amplitude as shown in FIG. 2A. The oscillator output is supplied to a zero crossover circuit 22 which produces one pulse at zero crossover for each applied sine Wave cycle as shown in FIG. 2B. These are referred to as the reference trigger pulses 2B. The circuit 22 may be any one of several suitable types well known in the art. One such type comprises limiters for squaring the Sine wave, a ditferentiator for producing a pulse of positive polarity `at the start (zero crossover) of one-half cycle of the square wave, and a blocking oscillator that is triggered by this positive pulse.

The reference trigger pulses are applied to a modulator trigger generator 23 Which comprises a blocking oscillator that is triggered by the applied pulses to produce modulator trigger pulses 2C as shown in FIG. 2C. The modulator trigger pulses are passed over a lead 37 to the modulator 16. The modulator 16 includes a coding circuit for producing periodically recurring pairs of pulses, the pairs having the desired code spacing. The modulator 16 also includes a suitable pulse generator such as one of the type comprising a pulse forming delay line.

A jitter control circuit 26 applies a periodically varying voltage to the blocking oscillator (FIG. 3) of generator 23 so that the modulator trigger pulses jitter. This jitter is a discrete amount as will be understood by referring to FIG. 2B and FIG. 2C. In FIG. 2 the modulator trigger pulse is illustrated for the case where the blocking oscillator has been triggered by reference trigger pulse 1 of FIG. 2B. The jitter control may make the blocking oscillator iire on one of the other reference trigger pulses such as pulse 2 or pulse 3. The units 23 (modulator trigger generator) and 26 (jitter control) are included in a module 1A17, the units of which are enclosed by dotted lines.

Now refer to FIG. 3 for certain circuit details given by way of example. The module 1A17 and circuit details of units 23 and 26 are shown in FIG. 3. The trigger generator 23 comprises a blocking oscillator which, in the example shown, comprises a transistor Q of the PNP type. The blocking oscillator transformer comprises a primary winding 27 in the collector circuit, a secondary Winding 28 in the base circuit, and an output winding 29. Minus 18 volts is applied to the collector of transistor Q through a G-ohm resistor and primary Winding 27. A filter capacitor 3L and a protective diode 25 are provided. Secondary winding 28 has one end connected through an adjustable resistor R11 to ground. The other end of secondary 28, which is driven negative when the oscillator fires, is connected through U a capacitor 32 an-d a diode 30 to the base of transistor Q. The emitter of transistor Q is connected to ground. When the blocking oscillator res, current ows from emitter to base, through diode 30, capacitor 32, and secondary 28 to ground. Thus, at the end of the pulse, capacitor 32 is charged and back biases diode 30. The negative reference trigger pulses being applied over lead 33 cannot trigger the blocking oscillator until sufficient charge has leaked off capacitor 32 to sufficiently reduce the back bias on diode 30.

The leakage path for capacitor 32 is through resistors R9, R8, R10, through the 1K resistor and the minus l8-volt power supply, to ground, and from ground through reisistor R11 and secondary 28. The leakage rate, after initial adjustment, is determined by whether resistor R9 shorted or remains effectively in the circuit. When shorted, the PRF is 140 pulses per second; when not shorted, the PRF is 30 pulses per second. The PRF is controlled as will be described later.

It may be noted that the blocking oscillator of trigger' generator 23 is not free-running, i.e., it must be triggered since transistor Q is normally biased to cut-off by the voltage drop across a diode 35 resulting from plus 18 volts connected to its anode through a 63K resistor.

The jitter control circuit 26 is a free-running relaxation oscillator comprising a capacitor 34 connected at one side to 120 vvolts D.C. yand connected at the other side through resistors R6 and R7 to ground. The capacitor is shunted by a neon lamp V1 which breaks down when capacitor 34 charges to a certain voltage. Thus, a low frequency (about cycles per second) sawtooth voltage yappears across resistor R7. The sawtooth voltage is coupled by a capacitor 36 to the discharge path of blocking oscillator capacitor 32, thus superimposing a wave in the PRF control RC network that jitters the PRF output of the modulation trigger generator by a few counts. This jitter is a discrete amount. For example, blocking oscillator 32 may fire on reference trigger pulse 1 as shown in FIG. 2, or it may tire on reference trigger pulses 2 or 3.

The modulator trigger pulses induced in output winding 29 are applied from trigger generator 23 to the output lead 37, and over the lead 37 to the modulator 16.

Track and search circuitry Reference is now made more particularly to the automatic track-in-range and automatic search-in-range circuitry. It has been stated that the modulator trigger pulses are supplied to the modulator 16. They are also supplied, referring to FIG. l, over a lead 41 to a variable delay generator 42 which is included in a module 1A10, the units of which are enclosed by dotted lines. The unit 42 may be a phantastron or the like which produces a gate pulse having a back edge which may be varied in timing as a function of an applied D.-C. voltage. This variable delay gate pulse 2H is shown in FIG. 2H. It is triggered or started by the modulator trigger pulse 2C (FIG. 2C);vit terminates at a time' that is a function of the D.C. voltage supplied over a lead 43 from the distance potentiometer 44. The potentiometer 44 is driven by the range motor 46 through a clutch-brake unit and gears as will be described in detail later.

The back edge of the variable delay pulse from generator 42 triggers a wide pulse gate generator 47 which may be a monostable multivibrator. The output of generator 47 is the 210 microsecond wide gate pulse 2J shown in FIG. 2J. This wide gate is applied to a precoincidence gate 48 for periodically gating through resolved trigger pulses 2G (shown in FIG. 2G) supplied from a zero crossover circuit 49. The pre-coincidence gate may be a coincidence circuit of any suitable type, such as a coincidence diode circuit.

The resolved trigger pulses 2G (FIG. 2G) are obtained as follows. The sine wave signal from timing oscillator 21 is supplied to the rotor of a resolver 51 which is driven, together with the distance potentiometer 44, by the range motor 46 through the clutch-brake unit and gears. Two out-of-phase output signals are obtained from the resolver stator windings. These output signals are supplied to a phase shifting network 52 in which they are added to produce a single phase-shifted sine wave signal, shown in FIG. 2F, which is phase shifted by an amount that is a function of the position of the resolver rotor. This signal is yreferred to as the resolved timing signal 2F.

The timing signal 2F is fed to the zero crossover circuit 49 which may be the same as the zero crossover circuit 22. Thus, the output of unit 49 is the resolved trigger pulses 2G (FIG. 2G).

Referring again to coincidence gate 48, the resolved trigger pulse of the pulses 2G that is coincident with the wide gate pulse 2J is passed by the gate 48. It is evident that the pulse repetition frequency (PRF) of the pulse output of gate 48 is the same as that of the modulator trigger pulses 2C.

The output pulses of gate 48 are applied to a range gate generator 53 which may be a monostable multivibrator that is triggered by the applied pulses to produce a range gate pulse 2K as shown in FIG. 2K. In the present example, the range gate pulse is 34 microseconds wide. It will now be evident that the time of occurrence of the range gate pulse 2K with respect to the modulator trigger pulse 2C is a function of the positions of the distance potentiometer 44 and the resolver 51 as set by the range motor 46.

The range motor 46 is driven by a servo power amplitier 54 which is under the control of a range error signal when the DME is in the acquisition and automatictrack-in-range modes, which is under the control of a velocity memory voltage when the DME is in the memory mode, and which is under the control of a search signal when the DME is in automatic search.

The range error signal is obtained as follows. The range gate pulses 2K are applied to a coincidence circuit 56 (part of module 1All7) which may be of the type comprising diodes. Also, the decoder video pulses 2E,

shown in FIG. 2E, are supplied from the decoder 19' to coincidence circuit 56. When a decoder video pulse is in time coincidence with the range gate pulse 2K as illustrated in FIG. 2, the decoder video pulse passes through the coincidence circuit 56 and is applied to a blocking oscillator 57 (module 1A17) to trigger this oscillator so that it produces one output pulse for each Iapplied trigger pulse 2E. These output pulses, which are 4 microseconds in width, are referred to as coincident video pulses. They are applied to an amplifier 58 (in module 1A12) which supplies the coincident video pulses as 36-volt pulses to a range error bridge 59 (also in module 1A12), and as 8-volt pulses to a multivibrator 61 in a module 1A11.

As noted above, the amplifier 5S and the bridge 59 are included in a module 1All2 as indicated by the enclosing dotted lines. This module also includes an amplifier and ringing circuit 62 which applies a range error ramp 2L, as shown in FIG. 2L, in the form of an S wave to the range error bridge 59. The ramp 2L is generated by the range gate 2K supplied from generator 53, and is time coincident with it. Therefore, the coincident video pulses will be coincident with some portion of the range ramp to produce a range error signalV unless the coincidence occurs at the center or zero crossover of the ramp, in which case there is no error signal.

FIG. 4 shows units of module 1A12 in more detail merely by way of example. The amplifier 58 comprises a NPN type transistor Q3 which is normally reversebiased by the voltage drop across a clamping diode CR3. The primary of an output transformer T1 is connected between the emitter of Q3 and ground. Transformer T1 has two secondaries 63 and 64. Upon occurrence of a coincidence video pulse, Q3 conducts to induce coincidence video pulses in the secondaries 63 and 64.

The pulses from secondary 64 are applied across the range error bridge as will be described later.

The range gate 2K is applied to the amplifier and ringing circuit 62 which comprises a PNP type transistor Q1 and an NPN type transistor Q2. The range gate is applied with negative polarity through a coupling capacitor 66 to the base of Q1. Preferably, the coupling capacitor 66 is preceded by a capacitor 24- which, with the load at Q1, functions as `a differentiating circuit to steepen the rise of the range gate. A resistor 38 shunts the capacitor 24 for passing the mid-portion of the range gate. Q1 is normally reverse-biased by the voltage drop across a clamping diode 67. During the application of the range gate, Q1 is forced into saturation thus producing a positive 18-volt pulse output at the collector of Q1. This output is applied through a coupling capacitor 68 and Q2 to the ringing circuit which comprises a capacitor C6 and an inductance coil L1. Q2 functions as an emitter-follower driving the series resonant circuit C6, L1. Q2 is normally reversed-biased by the voltage drop across a clamping diode 69.

During the period that Q2 is applying the range gate to the ringing circuit C6, L1, one cycle of a sinusoidal ramp voltage is produced by an interchange of energy between L1 and C6 to produce the range error ramp 2L. The oscillation is terminated when the range gate signal terminates, cutting oft Q2. The ramp voltage 2L is applied across one diagonal of the range error bridge 59.

The bridge 59 has a resistor and a diode in each of its four arms, the four arms containing, respectively, resistor 71 and diode CR4, resistor 72 and diode CRS, resistor 73 and diode CR6, and resistor 74 and CR7. The ramp voltage is applied to the bridge by a connection from the high voltage end of L1 to the junction of resistors 71 and 73, and by a connection from the other end of L1 through ground and through a storage or range error capacitor 7'6 to the junction of resistors 72 and 74.

The video coincident pulses induced in secondary 64 are connected across the other diagonal of the bridge 59, the upper end of secondary 64 being connected to the junction point of diodes CR4 and CRS, and the lower end of secondary 64 being connected through a 24-volt Zener diode 77 to the junction point of diodes CR6 and CR7. The Zener diode 77 acts as a threshold circuit to pass only signal above a certain voltage level and thus eliminate the lower voltage noise. Also, it maintains the current flow at a constant value since the input impedance (at secondary 64) is high. During the presence of each 36-volt, 4-microsecond pulse supplied from secondary 64, all four arms of the bridge are conducting. Therefore, during this 4microsecond interval the ramp voltage 2L (of 34 microseconds duration) is sampled to charge or -discharge capacitor 76 if the sampling occurs at one side or the other of the ramp zero crossover. If the 4-microsecond video coincident pulse is time coincident with the ramp zero crossover, the charge on storage capacitor 76 remains unchanged.

From the above it will be `seen that the polarity and amplitude of the voltage built up on capacitor 76 is a function of the position of the 4-microsecond video coincident pulse inside the 34-microsecond range gate. This video coincident pulse, it will be remembered, is generated in response to a ground beacon reply, and its timing corresponds to the time of receipt of said reply. Thus, if the video coincident pulse is centered on the ramp 2L (and thus centered in the range gate 2K) the timing of the range gate with respect to the time of transmission of a pair of interrogation pulses gives the desired range information. Therefore, the output voltage from capacitor 76 is used as the range error signal to control the operation of the range servo system.

The range error signal from capacitor 76 is supplied to the upper contact 78 of a relay K1, and to a relay arm 79 when it is in its upper position (K1 deenergized). From relay arm 79, the range error signal is supplied CFI through the resistor 81 of a lag-lead circuit, described later, and through resistor 82 and a coupling capacitor 83 to a servo pre-amplifier 84 lof high input impedance. The error signal is chopped by grounding the junction point of resistor 82 and capacitor 83 at a 400-cycle per second rate. This is done by applying a 400 cycle per second signal to the base of a transistor 86 which, when driven to conduction, connects the output of the lag-lead circuit to ground.

Amplified range error signal is `applied through a blocking capacitor 87 to the base of a transistor 88 which is the output stage of the pre-amplifier. The range error output signal is taken off the collector output resistor 89 and supplied, as shown in FIG. l, to a Iservo amplifier 91 which drives the range motor 46 through the servo push-pull power amplifier 54. The motor 46 is a conventional A.C. operated reversible servo motor. The servo amplifiers and feedbacks are conventional. To provide servo stabilization, tachometer feedback voltage is supplied from a tachometer 93 to the servo pre-amplifier as indicated. This feedback is proportional to the rate of rotation of the range motor. The tachometer feedback also serves to maximize the range velocity ratio.

It will be apparent that the range motor 46 is driven in one direction or the other depending upon the polarity of the range error signal, and that it is stopped if the range error signal becomes zero. Thus, when the DME locks in on a ground `beacon reply, the range gate is driven to keep it coincident in time with the reply pulse, i.e., the DME automatically tracks in range, and the angular position of the distance potentiometer shaft indicates the range `which may be read off a range indicator 92 comprising, for example, a range dial and pointer.

Mode switching The search-track control circuit in module 1A11 switches the DME from one mode of operation to another. As previously stated, there are four modes of operation, namely, (1) automatic track, (2) proportional memory, (3) automatic search, and (4) acquisition.

The module 1A11, referring to FIGS. 1 and 5, includes the relay K1 which is under the control of a pulse counter 94. It includes a velocity memory capacitor 96 which is also part of the lag-lead circuit. It includes a proportional memory circuit 97 which controls relays K2 and K3.

The operation and circuitry of the search-track control circuit of module 1A11 will now be described with reference to FIGS. l and 5. In FIG. 5, and also in FIGS. 3, 4, 8 and 9, some of the circuit values are given merely by way of example. Unless otherwise indicated, the values are in ohms, thousands of ohms (k), megohms (MEG), microfara-ds \(mf.), micro-microfarads (mmf), and microhenrics (ttm). The video coincidence pulses (which correspond to relay pulses) are supplied from the amplifier 58 of module 1A12 over a lead 98 to the multivibrator 61 of module 1A11 ywhich is of a conventional monostable type comprising transistors Q11 and Q12. Each S-volt 4-microsecond video coincidence pulse triggers multivibrator 61 to produce a negative 7-volt 1.5-multisecond width pulse which is applied to the base of an emitter follower transistor Q13 of the PNP type in the pulse counter 94. With Q13 conducting during the 1.5-millisecond pulse input, the Q13 emitter is driven negative and a capacitor 99 is charged through a diode 101 and the emitter of a transistor Q14 of the NPN type. This charge path is from plus l2 volts applied to the collector of Q14, through Q14, diode 101, capacitor 99, output resistor 102 and Q13. During this time a diode 103 remains reverse biased.

As soon as Q13 turns off and its emitter returns to ground potential, diode 101 becomes reverse biased and diode 103 becomes forward biased. This allows a portion of the charge stored by capacitor 99 to be transferred to a storage capacitor 104. This charge transfer path is from the positive side of capacitor 99, through diode 103, through storage capacitor 104 to the minus l2-volt supply applied to the collector of Q13, through the minus l2-volt supply to ground, and from ground through the output resistor 102 to the other side of capacitor 99.

Each successive coincident video pulse turns Q13 on and allows additional charge to be transferred from capacitor `99 to storage capacitor 104 after Q13 turns off. Thus, the voltage across capacitor 104 builds up in steps, one step for each coincident video pulse. The voltage build-up across capacitor 104 raises the base potential of Q14, and Q14 is forced to conduct harder. The receipt by the 4DME of three or four good amplitude ground -beacon reply signals out of nine or ten in succession will raise the voltage of storage capacitor 104 to a value which drives the'emitter of Q14 positive enough to de-energize the relay K1. This action takes pl-ace as follows. The relay coil :of K1 normally has col-lector current flowing through it from a PNP type transistor Q comprising r-elay amplifier 106, Q15 being forward biased by the minus 12-volt supply applied through a resistor 107. When Q14 conducts hard enough, its emitter becomes sufficiently positive to make a diode 108 conduct, thus applying positive voltage to the base of Q15 and turning off Q15 to de-energize K1. It will be noted that diode 108 is back biased by the minus l2- volt supply applied through the 24k resistor so that it normally is non-conducting.

Considering further the operation of pulse counter 94, the rate of voltage lbuildup on storage capacitor 104, and thus the potential buildup on the base of Q14, is controlled by the amount of resistance in the discharge path of capacitor 104. This discharge path is from the plus side of capacitor 104 through resistors 111, 112 and 113 to ground, and from ground through the minus 12-volt power supply back to the negative side of capacitor 104. The RC time constant of the discharge path is made shorter during the :search mode by shorting the resistor 112 through contacts of relay K2 as described later.

Consider now certain functions performed by relay K1, again referring to FIGS. l and S. In these figures, and in FIG. 4, the relay K1 is illustrated as de-energized; relays K2 and K3 are also shown de-energized; and the DME is in the automatic track-in-range mode. It will be noted that the two K1 relay coils shown in FIGS. 4 and 5, respectively, are connected in parallel, the K1 coil in FIG. 4 controlling relay arm 79. With K1 deenergized, range error signal is applied through arm 79 to the servo pre-amplifier 84, and the DME is tracking in range.

As shown in FIGS. 1 and 5, with K1 de-energized its arms 116 and 117 are in their lower position where 117 connects to an open circuit and arm 116 connects to a minus 18-volt supply. This 18 volts is now connected through a lead 118 to the proportional memory circuit 97 as will be discussed later. For applying a search voltage to the servo pre-amplier 84 when K1 is energized, the relay arm 116 is also connected through a diode 119, resistors 121 and 122 to the relay ar-m 123 of relay K3. This arm connects to ground when K3 is de-energized, as in the illustrated track mode, and connects to a lead 124 when K3 is energized, thus applying a search voltage to lead 124, and also shorting velocity memory capacitor 96. The level of the search voltage is controlled by a variable resistor 127 which together with resistor 121 acts as a voltage divider. The search volt-age is supplied, during the search mode, over lead 124 and, referring to FIGS. 1 and 4, through a resistor 126 to the junction point of resistor 81 of the lag-lead network and resistor 82. The lag-lead network comprises resistors 81, 126 and capacitor 96.

During the track mode the velocity memory capacitor 96 is charged by the range error voltage supplied from the range error capacitor 76 (FIG. 4). This error signal is fed through resistors S1 and 126, lead 124 to velocity memory capacitor 96, and through relay arm 123 to ground. As a part of the lag-lead network capacitor 96 stores the time integral of range error. The greater the velocity of the airborne DME with respec-t to ground station, the greater the range error voltage, and the greater the charging voltage applied to the velocity memory capacitor 96.

It should now be noted that the complete lag-lead network consists of the resistors 81 and 126 (FIG. 4) and the velocity memory capacitor 96 (FIG. 5), capacitor 96 actually performing two functions. The laglead network when in the circuit causes the servo to have a comparatively slow response, and be non-responsive to noise. The servo response is fast when capacitor 96 is shorted by relay arm 123 with greater acceleration capability; it is comparatively slow when capacitor 96 is not shorted.

As previously mentioned, the range gate is driven comparatively fast for search and comparatively slow for track as determined by the clutch-brake unit and gearing mechanism. This slow or f-ast drive is under the control of relay K1 in cooperation with relay K3 as indica-ted in FIGS. l and 5. The clutch-brake unit, in effect, shifts gears for fast or slow drive, the set of gears through which the range motor 46 is driving depending upon whether a clutch control lead 128 is grounded or ungrounded as described in detail later. Since this part of the description is concerned with the DME operation without the incorporation of the search velocity control circuit, it is assumed that the lead 12S (FIG. 1) is unbroken, rather than broken at leads x and y as illustrated. With DME in the track mode, K1, K2 and K3 being deenergized as illustrated, arm 117 of K1 is disconnected from clutch control lead 128 and the lead is ungrounded. Thus, the range motor 46 is driving the distance potentiometer 44 and resolver S1 through the slow driving gear train.

When K1 is energized, as in the search mode, and providing K3 is energized, as it is in the search mode, the clutch control lead 12S is connected to ground by way of K1 arm 117 and the arm 129 of relay K3. Thus, the clutch has been lactuated so that the range motor 46 is now driving through the fast driving gear train.

From the foregoing it will be noted that relay K3 functions for clutch-brake control by action of its arm 129, and that it also functions at the vel-ocity memory capacitor 96 by action of its arm 123 for either shorting the memory capacitor or connecting its upper side to ground. Both relay K3 and relay K2 are controlled by the proportional memory circuit 97. Relay K2 performs two functions. The position of its arm 131 determines the pulse repetition frequency (PRF) of the transmitted interrogation pulses, the PRF being higher during the search mode than during the track mode; and the position of its arm 132 determines whether or not resistor 112 of pulse counter 94 is shorted. Resistor 112 is shorted during the search mode when the PRF is high so that the discharge circuit of storage capacitor 104 has a shorter time constant. During the track mode, when the PRF is comparatively low, the resistor 112 is not shorted.

The proportional memory circuit 97 will now be described. Its main function is to make the duration of the memory mode proportional to the length of time that the DME has been in the track mode. In the absence of proportional memory, any time that the DME went into the memory mode it would stay in that mode for some fixed period such as ten seconds. Thus, in this example, there would always be an interval of ten seconds before the DME could go into the search mode. With proportional memory the DME will remain in the memory -modei for only a short interval, such as two or three seconds, if the DME has been in the track mode for only `a short interval. If it has been in the track mode for a comparatively long period and then goes into the memory mode, it will stay in the memory mode for the maximum period which, in the present example is about ten seconds.

It will be seen that the driving of the servo by the velocity memory capacitor 96 is terminated as soon as the K3 relay arm 123 shorts capacitor 96 and connects the search voltage to the lead 124. At this point it may be noted that the search voltage is plus 15 volts taken from the junction point of voltage divider resistors 133 and 1341 when the K1 relay arm 116 is in its upper (energized) position.

Upon fading or loss of the ground station reply signals, the DME goes from the track-in-range mode to the memory mode as a result of relay K1 being energized. During the memory mode the relays K2 and K3 remain deenergized, the condition shown in FIGS. 1 and 5. Thus, at the start of the memory mode, K1 arm 116 is in the up position applying plus 15 Volts to lead 11S, land K1 arm 79 (FIG. 4) is down to disconnect the servo from the range error signal. The servo is now being driven by the voltage built up on velocity memory capacitor 96 during the track mode.

Consider now the action of the proportional memory circuit 97 during the two modes preceding the memory mode, namely, the track mode and the acquisition mode (which precedes the track mode). In these two modes the relay K1 is de-energized, its arms being in the position illustrated. Therefore, during these two modes K1 arm 116 is connected to minus 18 volts which is applied over lead 118, through a resistor 136 to the high capacity proportional memory capacitor 137, and from capacitor 137 through a 4.7k resistor to plus 18 volts. `It will be noted that this charging circuit for capacitor 137 has a long time constant, the capacity of 137 being 430 microfarads. It is evident that the longer the DME is in the track mode, the greater the charge acquired by capacitor i137.

As soon as relay K1 is de-enerfgized (i.e., at the start of the acquisition mode) the capacitor 137 starts to charge negatively. In a fraction of a second capacitor 137 char-ges negatively enough to turn off a transistor Q16 of the NPN type. This permits an acquisition control capacitor 139 .to be charged positively from the plus 18volt lsupply through the 'collector resistor 141 of Q16, capacitor 139 being between the base and grounded collector of a PNP type transistor Q17.

In about 0.75 second capacitor 139 charges positively enough .to turn oi the transistor Q17. This results in the turning ol of a PNP type transistor Q18. Thus, the relays K2 and K3 are de-energized since they receive their energizing current from the collector of Q13. This interval of about 0.75 second is the acquisition mode period. As soon as relays K2 and K3 are de-energized, the acquisition mode 'has .terminated and the DME is in the track mode. It should be noted that during the acquisition mode period the relays K2 and K3 are energized so that the PRF of the -interrogation pulses is high and .the time constant of the discharge path for the stepcharged capacitor 104 is short.

Referring again to the charging of the proportional memory capacitor 137, this capacitor will continue to charge negatively until its voltage is clamped by a diode 142 at a level determined by a voltage divider comprising resistance 143 and 144 connected between minus 18 volts and ground. Approximately ten seconds are required to reach the clamp voltage. If the DME is in track (and acquisition) for less than ten seconds, the clamp voltage is not reached.

Now consider the proportional memory operation when reply ysignals are lost so that relay K1 is energized, and the DME goes into the memory mode. The relays K2 and K3 remain de-ener-gized during the memory mode, and are energized at the end of the memory mode as will now be described. With K1 energized, its arm 116 is in the upper position applying plus 15 volts through the lead 118 and resistor 136 to proportional memory capacitor 137. Capacitor 137 is now charged in the opposite direction at approximately the same rate as before. After a period approximately equal to the original charging time (for the negative charging) of capacitor 137, the transistor Q16 is forward biased and conducts. This -period is a maximum of about ten seconds, and is a shorter period if the DME is in the track mode for a shorter period. The forward biasing of Q16 energizes relays K2 and K3, the K3 arm shorting the velocity memory capacitor 96, `thus ending the memory mode. The energizing of relays K2 and K3 occurs when Q16 is forward biased since conduction of Q16 drives Q17 into conduction. By Virtue of Q17 conducting, the voltage divider network 146, 147, 148 places a negative potential of the base of Q18 which turns it on and energizes relays K2 and K3 ending the memory mode. It is evident ,that the duration of the memory mode is proportional to the length of time the DME is in the track mode, up to a maximum of about ten seconds. Therefore, the DME is allowed to go into the search mode fairly promptly if it has been in the track mode for only a few seconds, such as three or four seconds.

At the end of the memory mode the three relays K1, K2 K3 are energized and the DME is in the search mode with the Search voltage being applied to the lead 124 and thus to the servo pre-amplier 84 .through diode 119, resistors 121 and 122, and K3 arm 123; the resistor 112 of the pulse counter is shorted; and K2 arm 131 has shorted R9 of the blocking oscillator (FIG. 3) so the PRF is high. Also, K1 arm 117 and K3 arm 129 have grounded the clutch control lead so that the range gate is being driven fast from 0 to 200 miles to locate the ground station reply signal.

When the range gate nds the reply signal (becomes time coincident with it), if three or four reply pulses out of nine or ten successive pulses, for example, get through the range gate, the .pulse counter de-energizes K1 and the DME is in the acquisition mode. The range error signal is now being applied to the servo pre-amplifier 84 (FIG. 4), ground has been taken oft the clutch control lead so that there is now slow servo drive of the range gate, and the lead 118 (FIG. 5) now applies minus 18 volts to the proportional memory capacitor 137 and to the base of Q16 resulting, after about 0.75 second, in the `de-energizing of K2 and K3 as .previously explained. The system is now in the track mode.

As shown in FIG. 1, there is la warning llag associated with the range indicator 92. The flag is masked and not visible when the range indicator is presenting a correct range reading as is the case when the DME is in the track mode. When the DME is in search, for example, the ag lis pulled from behind the mask by a `spring so that an operator is warned that the range indi cation .is not correct.

During the track mode the warning ag is held behind the mask by an energized solenoid 150. The solenoid is energized when a lead 151 is grounded, as it is when the relay K3 (FIG. 5) is de-energized so that the relay arm 129 is in the upper position. This is the condition illustrated, the DME being illustrated as being in the track mode.

The sequence of operation of the DME through its four modes of operation will now be summarized.

I. Track mode:

Relays K1, K2 and K3 are de-energized.

The range error signal is being applied to the servo input so that the range motor is driving the distance potentiometer and the resolver to hold the range gate (and the range error ramp) substantially centered with respect to the ground station reply signal so that there is automatic track-in-range.

The DME is in slow servo drive (clutch control lead 128 being ungrounded), and the servo has slow response (capacitor 95 being in the lag-lead network).

The PRF is 30 pulses per second, and the time constant is `correspondingly long for the discharge circuit of 13 the step-charged capacitor 104 in pulse counter circuit 94 so that capacitor 104 will hold a charge longer whereby there is less tendency for relay K1 to be momentarily energized.

Meanwhile a velocity memory voltage builds up on velocity memory capacitor 96.

Also, a negative charge is building up on proportional memory capacitor 137.

II. Proportional memory mode:

Relay K1 is energized. Relays K2 and K3 remain deenergized.

Upon loss of reply signals, step-charged capacitor 104 of pulse counter 94 loses its charge, K1 is energized, and the DME goes into the proportional memory mode. The duration of this mode is proportional to the time the DME has been in track, and has a maximum period of about ten seconds.

During proportional memory the voltage of velocity memory capacitor 96 is applied to the input of the servo pre-amplilier so that the range gate will continue to move in range at the aircrafts last velocity.

The DME is still in slow servo drive, and the servo still has slow response.

The PRF is still 30 pulses per second, and there is still a long time constant for the discharge circuit of the stepcharged capacitor 104.

If, while the DME is still in the memory mode, the reply pulses return reliably enough so that three or four reply pulses out of ten interrogation pulses pass through the range gate, the DME returns to the track mode.

If the reply pulses do not return soon enough, the DME goes into the search mode. It will be about ten seconds before the DME goes into search if the DME has been in track for ten seconds or more. However, the DME will go into search in a shorter time if it has been in track for less than ten seconds. For example, if the DME has been in track for -only about four seconds when reply signals are lost, the DME will be in the memory mode for only about four seconds, and will then go into search.

As previously explained, when the DME goes into the memory mode, the de-energizing of K1 connects lead 118 to plus 15 volts, thus starting the discharge of proportional memory capacitor 137. When capacitor 137 discharges to a certain voltage, relays K2 and K3 are energized as previously explained, and the memory mode is terminated. The DME is now in the search mode.

III. Search mode:

Relays K1, K2 and K3 are energized.

K3 relay arm 123 has now shorted memory (and lag-lead) capacitor 96, and has connected the D.-C. search voltage through lead 124 to the input of the servo pre-amplifier 84.

The DME is now in fast servo drive (clutch control lead 128 being grounded), and the servo has fast response (capacitor 96 being shorted).

The PRF of the interrogating pulses is now 140y pulses per second, and the time constant for the discharge circ-uit of the step-charged capacitor 104 is correspondingly short, resistor 112 having been shorted.

The range motor is now driving the distance potentiometer and the resolver so that the range gate is being swept rapidly through the 20D-mile range.

When the range gate occurs at the same time as the reception of reply pulses, and if at least three or four reply pulses out of nine or ten successive pulses pass through the range gate, the step-charged capacitor 104 of pulse counter 94 is charged to a voltage that causes K1 to be de-energized. Relays K2 and K3 remain energized. The DME is now in the acquisition mode.

IV. Acquisition mode:

Relay K1 is deenergized. Relays K2 and K3 are energized.

The duration of this mode is about 0.75 second.

Range error signal now is being applied to the input of the servo pre-amplifier.

The DME is now in slow servo drive (clutch control lead 128 now being ungrounded), but still has fast servo response since memory and lag-lead capacitor 96 is still shorted.

The PRF is still pulses per second, and there is still the correspondingly short discharge time constant for the step-charged capacitor 104.

If at least three or four reply pulses out of nine or ten interrogation pulses continue to pass through the range gate for the duration of the acquisition mode, the relays K2 and K3 are de-energized at the end of the acquisition mode, and the DME has returned to the track mode.

If less than these three or four reply pulses pass through the range gate during the acquisition imode, the relay K1 is energized, and the DME goes back into the Search mode. This switching back into search occurs promptly because of the short discharge time constant of the step-charged capacitor 104, resistor 112 being shorted.

By maintaining, during the acquisition mode, a high PRF for the interrogation pulses and a short discharge time constant for the step-charged capacitor 104, the duration of the acquisition mode can be made very short (0.75 second in this example) and still have an acquisition mode that is long enough to insure that the DME is not thrown into track by random pulse pairs that are being continuously transmitted from the ground station, these being referred to as squitter pulses. The use of a low PRF, such as a PRF of 30, would require an acquisition mode period of about four seconds to provide equally good insurance against squitter pulses throwing the DME into track. Furthermore, with the high PRF and short discharge time constant, the reception of squitter pulses usually de-energizes the relay K1 for only a very short interval, such as one-tenth second. This is a much shorter interval than it would be if the PRF were low with a long discharge time constant. The result is that by the use of the high PRF and short discharge time constant during the acquisition period, the DME is promptly thrown back into the search mode following reception of squitter pulses that are coincident with the range gate. Thus, the DME searches quickly and locks on to the actual reply pulses Without the search process being continually interrupted for intervals that would add up to a very substantial time.

During the acquisition mode the servo has fast response since the lag-lead capacitor 96 is shorted during this mode. It will be remembered that when the DME goes into the acquisition mode, the range error signal is applied to the servo input circuit. The fast servo response provides improved operation because the range error ramp will quickly be moved to a position where it is centered with respect to the reply signal so that when the DME is switched into the track mode the range reading immediately will be the correct reading. The rapid positioning of the range gate in the acquisition mode requires a range servo acceleration capability and fast response not required, or desired during the track and memory mode.

Clutch-brake drive In the example illustrated, the range motor 46 (FIG. l) drives the distance potentiometer 44 and the resolver 51 through a clutch-brake and gear drive as previously described. This drive is shown in more detail in FIGS. 6 and :7. First referring to the clutch-brake unit, it comprises a rotatable shaft 156 to which is attached a clutch plate 157 and a brake plate 158. The shaft 156 extends through and is rotatably supported by a coaxial shaft 159. Shaft 159 is rotatably supported by the end of a a metal housing 161.

One end of the shaft 159 carries a slutch plate 162 which faces the clutch plate 157. The other endv of the shaft 159 has a gear wheel 165 attached thereto which is driven by the range motor 46 through gear wheels 163 and 164. The gear 164 has the same number of teeth as the gear 165.

As illustrated in FIG. 6, the clutch is engaged due to the `action of a spring 166 which forces the shaft 156 to the right, and thus causes the clutch plate 157 to engage the Clutch plate 162.

In response to the energizing of a solenoid, indicated schematically by the coil 167, the shaft 156 is pulled to the left, thereby disengaging the clutch 157-162 and stopping the shaft rotation quickly by forcing the brake plate 158 against a brake plate 168 which is attached to the housing 161. It will be seen that when the solenoid 167 is de-energized (the clutch engaged), the range motor 46 drives the shaft 156 and a gear wheel 169 attached thereto; and that when the solenoid 167 is energized, the clutch is disengaged and the brake is applied so that the rotation of the shaft 156 is quickly stopped.

As shown in FIG. 7, the gear Wheel 164 is fastened to the bevel gear 171 of a differential. The gears 164 and 171 are rotatable about a differential shaft 172. A gear wheel 17-3 is driven through an idler gear 174 by the gear wheel 169 (FIG. 6). The gear 173 has a different nurnber of teeth than the gear 169. In the example described it is a difference of one tooth, the gear 173 having 61 teeth and the gear 169 having 60 teeth. The gear 173 is fastened to the bevel gear 176 of the differential, and both gears are rotatable about the differential shaft 172.

The bevel gears 171 and 176 mesh with a bevel gear 178 which is rotatable about a supporting shaft 177. The shaft 177 is mounted on a supporting block 179 which is fastened to the differential shaft 172.

It will be apparent that, in operation, if the gear Wheel 173 is held stationary (the brake on) while the gear wheel 164 is being driven, the bevel gear 171 will drive the bevel gear 178 around the bevel gear 176 and rotate the shaft 172 at a comparatively fast rotation.

Comparatively slow rotation of the shaft 172 is obtained when the clutch is engaged so that both the gear 173 and the gear 164 are rotating. Because of the idler gear 174, the gears 173 and 164 (and bevel gears 176 and 171) rotate in opposite directions; and because of the one tooth difference in gears 169 and 173 they rotate at slightly different speeds. Thus, the shaft 172 is rotated at a comparatively slow speed.

It will be noted that the shaft 172 drives the distance potentiometer 44 through gears 181 (FIG. 6) and that it drives the resolver 51 through gears 182. The gearing is such that the resolver rotor is rotated ten times for each single rotation of the potentiometer arm.

As previously explained, in the search mode the clutch control lead 12S (FIG. 1) is grounded so that the clutch is disengaged, the brake is on, and the DME is in fast servo drive; that is, the range motor 46 drives the range units 44 and 51 at the high speed. As soon as the range gate becomes coincident with the reply pulses and sucient reply pulses pass through the range gate, the lead 128 is ungrounded so that the solenoid 167 is de-energized. The result is that the clutch is very quickly engaged by action of the spring 166 to put the DME in slow servo drive. Thus, the DME is in slow servo drive during the acquisition mode. It is also in slow servo drive during the track and proportional memory modes.

When, during search, the range gate becomes coincident with the reply pulses, it must be stopped very rapidly, i.e., switched very quickly to the slow drive so that there will be a lock-on for automatic track. During the search mode the range gate is being driven very rapidly, the gate travel rate being at forty miles per second or about 500 microseconds per second. The gate Width of 34 microseconds is wide enough to allow three or four out of nine or ten successive replypulses, for example, to pass through the range gate before it has time to move out of coincidence. Also, the system switches to slow servo drive fast enough so that the range gate is not driven out of coincidence with reply pulses before the system can lock on to the reply pulses. In the example described, the stopping time for the range servo, i.e., the time for shifting from fast servo drive to slow servo drive, is not greater than three milliseconds.

Search velocity control circuit Up to this point the DME has been described as it would operate without the automatic search velocity control. It will be recognized that without this search velocity control the DME will search very rapidly in range during times that the DME is outside the operating range of a ground station being interrogated. This unnecessarily shortens the life of the servo motor, gears and other electromechanical units of the DME.

The DME is provided with automatic search velocity control, one embodiment of which will now be described. Refer to FIGS. l and 8. In the example illustrated, the search velocity control circuit, indicated at 251, is connected to receive negative polarity pulses from the decoder 19. In the slow search condition (DME outside the beacon range) a relay coil 266 of the standby circuit is deenergized and the relay arm 267 is open (in the dotted line position) so that the leads x and y are not connected together. As shown in FIG. 1, the clutch control lead 128 is broken and connections made through the leads x and y to the elay arms of the relay coil 266. When relay coil 266 is energized, as it is when the DME gets within the working range of the ground beacon, the relay arms are closed to complete the circuit through the clutch lead 128. Only under this condition can the grounding of lead 128 by relays K1 and K3 in module 1A11 energize the solenoid 167 of the clutch-brake and throw the DME into its fast search.

As shown in FIG. 8, the standby circuit comprises a PNP type transistor Q21 which has an output resistor 252 connected between the emitter and a variable tap 250 on a potentiometer 253. Q21 is normally maintained cutoff by the voltage drop across a diode 254 that is conducting because of plus 18 volts applied to its anode through a resistor 256.

Negative pulses from decoder 19, when present, are applied to the base of Q21 through a current limiting resistor 257 and an isolating capacitor 258. These pulses appear as negative pulses across output resistor 252. They are made to bypass the potentiometer 253 by means of a capacitor 259.

The output circuit of Q21 is coupled through an integrating or pulse stretching circuit 261 and a diode 262 to the base of a PNP type transistor Q22. Q22 is normally maintained cutoff by the voltage drop across a diode 263 that is conducting because of plus 12 volts applied to its anode through a resistor 264. It will also be noted that a back bias voltage is applied to diode 262 so that normally it is open. This bias is applied from the variable tap 250 on potentiometer 253 through output resistor 252 and a resistor 271 to the cathode of diode 262. Thus, in the absence of pulses applied to the search velocity control circiut from the decoder 19, Q22 is cut off and the relay 266 in the collector circuit of Q22 is held de-energized. A capacitor 265 is connected from the collector of Q22 to ground to further integrate pulses from the decoder 19 passing through the amplifiers Q21 and Q22. With Q22` de-energized, the relay arm 267 is in its open (dotted line) position so that the clutch control lead 128 (FIG. 1) is broken, thus putting the DME into slow servo drive.

As the airborne DME approaches a selected ground station with the DME searching-in-range but being held in slow servo drive by the search velocity control, the DME will get close enough to the ground station so that negative video pulses will appear in the output circuit of decoder 19 and be supplied to the input of the search velocity control circuit 251. These pulses are applied to the base of Q21 and appear as negative pulses at the emitter of Q21. Each emitter output pulse charges a capacitor 272 of integrating circuit 261 to the peak of the pulse. At the end of the pulse, capacitor 272 will begin to discharge through resistor 252 towards the voltage at the tap 250 of potentiometer 253. The resulting negative stretched pulses are fed into the integrator comprising the resistor 271 and a capacitor 273 yielding a D.C. voltage across capacitor 273 equal to the integral of the stretched pulses.

When the airborne DME gets close to the working range of the ground station there will be suicient pulses of su'lcient amplitude appearing at the emitter of Q21 to make the voltage across integrating capacitor 273 suiciently negative to forward bias the diode 262 and apply a negative voltage to the base of Q22. Q22 now conducts, relay 266 is energized, and relay arm 267 is pulled to its closed position. This closes the circuit through the clutch control lead 128 (which, referring to FIG. 1, is grounded through relay arms 171 and 129 of relays K1 and K3) and throws the DME into fast servo drive. The DME is now in full operation so that it searches very rapidly in range until it locks onto the reply pulses and goes into automatic track-in-range.

The negative voltage at which diode 262 conducts is referred to as the threshold voltage. The threshold value may be adjusted by adjusting the potentiometer tap 250. The threshold preferably is adjusted so that the DME is turned on to full operation just before the DME has reached the capability of acquiring and tracking the ground station.

An example of a suitable threshold setting is one that causes the threshold to be exceeded when 1000 decoded pulses per second (decoder video) are applied to the search velocity control circuit. The number of decodings per second, i.e., the number of pulses from the decoder, will increase the maximum of about 3600 as the DME arrives close enough to the ground beacon so that there is a strong signal. It may be noted that, in normal operation, a suitable setting for the DME receiver gain is one where there are from 200 to 500 random decodings produced by random noise.

The invention may be utilized in cooperation with a ground beacon that transmits only in response to interrogation by the DME, as, for example, with a ground beacon -to be used with an instrument landing system. In that case the beacon would transmit a maximum of 140 pulses per second when interrogated by the DME here described, and the control circuit would be given circuit values and a threshold adjustment that would cause the threshold to be exceeded by something less than 140 pulses per second, such as 5() pulses per second, being applied to the search velocity control circuit.

FIG. 9 illsutrates another embodiment of the invention. This figure shows only the portions of the module 1A11 and of the Search velocity control circuit that are necesary for an understanding of this embodiment. The remainder of the circuits are shown in the previously described FIGS. 5 and 8.

This second embodiment is incorporated into the DME as previously described for operation without any search velocity control. Specifically, the embodiment of FIG. 9 is incorporated in the DME illustrated in FIG. 1, but with the clutch control lead 12S unbroken at x, y, the leads x and y being omitted. Also, the relay arms of relay 266 in the standby circuit are as shown in FIG. 9, rather than as shown in FIGS. 1 and 8.

In this second embodiment, a resistor 274 is provided in module 1A11 so that the search velocity control circuit can connect it across the voltage divider resistor 134 of module 1A11 (FIGS. 1 and 5). The resistor 274, of 220 ohms value in this example, is connected between the upper end of resistor 134 and a relay contact 276 of relay 266 in the search velocity control circuit. When relay coil 266 is de-energized (the DME in slow search), the

relay arm 277 is in the dotted position illustrated and connects the lower end of resistor 274 to ground, and thus across voltage divider resistor 134.

It will be recalled that when the DME is thrown into the search mode, the relays K1 and K3 are energized (the de-energized position being shown in FIG. 9) and approximately +0.5 volt is applied through the search voltage lead 124 to the servo preamplifier to drive the DME in vary rapid search-in-range. With the presently described search velocity control embodiment, if signals from the ground beacon are absent or not strong enough, the arm 277 of de-energized relay 266 is in the upper dotted line position so that the low resistance resistor 274 is connected across voltage divider resistor 134. As a result the search voltage appearing at the junction point of voltage divider resistors 133 and 134 is reduced from +15 volts to about +1.5 volts. Now the search voltage that is applied to the servo preamplifier is only 0.05 volt, with the result that the servo drive is greatly reduced in speed. Since the distance potentiometer, resolver, gears, etc. are driven at this comparatively low speed while the DME is outside the working range of the ground beacon being interrogated, the wear on these parts is reduced so that they have a longer life. Because the DME search-i -range has not been stopped, failure of any portion of the search velocity control circuit cannot prevent thc DME from performing its basic function of measuring distance.

A-s soon as the DME gets close to or within the working range of the ground beacon being interrogated, the relay coil 266 of the search velocity control circuit is energized, arm 277 is pulled down to disconnect resistor 274 from ground, the search voltage of approximately +0.5 volt is applied to the servo pre-amplier, and the DME proceeds to search in range at its extremely fast search rate for quickly finding and locking on to the beacon replay pulses.

What is claimed is:

1. Pulse radar equipment comprising a transmitter, means for causing said transmitter t-o transmit pulses, receiving means for receiving return pulses in response to said transmission, means for producing a range gate which may be varied in time with respect to said transmitted pulses, search means for causing said range gate to Search rapidly in range until it is coincident in time with said return pulses, lmeans responsive to said coincidence for causing said equipment to track automatically in range, an automatic search velocity control circuit to which output pulses from said receiving means are ap plied, said control circuit comprising means responsive to said applied pulse-s for reducing the speed of said searchin-range in response to fading or loss of said applied pulses.

2. Distance measuring equipment that is to be airborne and is to interrogate a selected ground transponder station, said equipment comprising a transmitter, means for causing said transmitter to transmit interrogation pulses to said selected ground station, receiving means for receiving from said ground station coded reply pulses in response to said interrogation, said receiving means including a decoder for decoding said reply pulses, means for producing a range gate which may be varied in time with respect to said interrogation pulses, search means for causing said range gate to search rapidly in range until it is coincident in time with said reply pulses, means responsive to said coincidence for causing said equipment to track automatically in range, an automatic control circuit to which output pulses from said decoder are applied, said control circuit comprising means responsive to the output of said decoder `for reducing the speed of said search-in-range in response to fading or loss of said decoder output.

3. Distance measuring equipment that is to interrogate a selected transponder, said equipment comprising a transmitter, means for'causing said transmitter to transmit interrogation pulses to said selected transponder, re-

ceiving means for receiving from said transponder reply pulses in response to said interrogation, means for producing a range gate which may be varied in time with respect to said interrogation pulses, search means for causing said range gate to search-in-range until it is coincident in time with said reply pulses, means responsive to said coincidence for causing said equipment to track automatically in range, an automatic control circuit to which output pulses from said receiving means are applied, a voltage threshold circuit, means for integrating said applied pulses to obtain a control voltage which is applied to said threshold circuit, and means for reducing the speed of said search-in-range in response to said control voltage falling below the threshold voltage of said threshold circuit.

4. Distance measuring equipment that is to be airborne and is to interrogate a selected ground transponder station, said equipment comprising a transmitter, means for causing said transmitter to transmit interrogation pulses to said selected ground station, receiving means for receiving from said ground station coded reply pulses in response to said interrogation, said receiving means including a decoder for decoding said reply pulses, means for producing a range gate which may be varied in time with respect to said interrogation pulses, search means for causing said range gate to search-in-range until it is coincident in time with said reply pulses, means responsive to said coincidence for causing said equipment to track automatically in range, an automatic control circuit to which output pulses from said decoder are applied, a Voltage threshold circuit, means for integrating the output of said decoder to obtain a control voltage which is applied to said threshold circuit, and means for reducing the speed of said search-in-range in response to said control voltage falling below the threshold voltage of said threshold circuit.

5. Distance measuring equipment (DME) comprising means for transmitting interrogation pulses and means for receiving reply pulses in response to transmission of said interrogation pulses, and further comprising means for producing a range gate pulse that is shiftable in time with respect to an interrogation pulse, a ranging unit for controlling the timing of said range gate, range driving means for selectively driving said ranging unit at either a comparatively high speed or at a comparatively low speed, mode switching means for automatically switching the DME into an automatic track-in-range mode in response to received reply pulses passing through said range gate and including means for selecting the low speed drive of the ranging unit, mode switching means for automatically switching the DME from the track-in-range mode to a memory mode in response to loss of reply pulses with the DME still in low speed drive of the ranging unit, mode switching means for automatically switching the DME from the memory mode to a search-in-range mode upon failure of reply pulses to return quickly enough to return the DME to the track-in-range mode and including means for selecting the high speed drive of said ringing unit, and mode switching means for automatically switching the DME from the search-inrange mode to an acquisition mode in response to the receipt of reply pulses that pass through said range gate and including means for selecting said low speed drive of the ranging unit, said DME switching to the track-inrange mode at the end of the acquisition mode period if a sulcient number of received reply pulses pass through the range gate during the acquisition mode period, and an automatic search velocity control circuit comprising means responsive to output pulses of said receiving means for putting said range driving means into its low speed drive during the search-in-range mode in response to fading or loss of said output pulses and thereby reducing the speed of said search-in-range.

6. Distance measuring equipment (DME) comprising means for transmitting interrogation pulses and means for receiving coded reply pulses in response to transmission of said interrogation pulses, said receiving means including a decoder for decoding said reply pulses, and further comprising means for producing a range gate pulse that is shiftable in time with respect to an interrogation pulse, a ranging unit for controlling the timing of said range gate, range driving means for selectively driving said ranging unit at either a comparatively high speed or at a comparatively low speed, mode switching means for automatically switching the DME into an automatic trackin-range mode in response to received reply pulses passing through said range gate and including means for selecting the low speed drive of the ranging unit, mode switching means for automatically switching the DME from the track-in-range mode to a memory mode in response to loss of reply pulses with the DME still in low speed drive of the ranging unit, mode switching means for automatically switching the DME from the memory mode to a search-in-range mode upon failure of reply pulses to return quickly enough to return the DME to the trackin-range mode and including means for selecting the high speed drive of said ranging unit, and mode switching means for automatically switching the DME from the search-in-range mode to an acquisition mode in response to the receipt of reply pulses that pass through said range gate and including means for selecting said low speed drive of the ranging unit, said DME switching to the trackin-range mode at the end of the acquisition mode period if a suicient number of received reply pulses pass through the range gate during the acquisition mode period, and an automatic control circuit comprising means responsive to output pulses from said decoder for putting said range driving means into its low speed drive during the searchin-range mode in response to fading or loss of said decoder output pulses and thereby reducing the speed of said search-in-range.

7. Distance measuring equipment (DME) comprising means for transmitting interrogation pulses and means for receiving reply pulses in response to transmission of said interrogation pulses, and further comprising means for producing a range gate pulse that is shiftable in time with respect to an interrogation pulse, a range motor, a ranging unit for controlling the timing of said range gate, gear drive means having -two dierent gear ratios either one of which may be selected to couple said motor to said ranging unit, a single servo channel which has its output coupled to said motor for driving it, mode switching means for automatically switching the DME into an automatic track-in-range mode in `response to Ireceived reply pulses passing through said range gate and including means for applying a range error signal to the input of said servo channel and including means for selecting a certain one of said gear ratios for slow drive .of the ranging unit, mode switching means for automatically switching the DME from the track-in-range mode to a memory mode in response to loss Iof reply pulses with the DME still in slow servo drive of the ranging unit, mode switching means for automatically switching the DME from the memory mode to a search-in-range mode upon failure of reply pulses to return quickly enough to return the DME to the track-in-range mode and including means for applying a range search signal to the input of said servo channel and including means for selecting the other of said gear ratios for fast drive of said ranging unit, mode switching means for automatically switching the DME from the search-in-range mode to an acquisition mode in response to the receipt of reply pulses that pass through said range gate and including means for applying a range error signal to the input of said servo channel and including means for selecting said certain one of said gear ratios for slow drive Iof the ranging unit, said DME switching to the track-in-range mode at the end of t'he acquisition mode period if a su'icient number of received reply pulses pass through the range gate during the `acquisition mode peri-od, and an auto-` matic search velocity control circuit comprising means responsive to output pulses of said receiving means for reducing the strength of said range sea-rch signal in response to fading or loss of said output pulses and thereby reducing the speed during said search-in-range mode.

8. Distance measuring equipment (DME) comprising means for transmitting interrogation pulses and means for receiving coded reply pulses in response t transmission of said interrogation pulses, said receiving means inclu-ding a decoder for decoding fsaid reply pulses, and further comprising means for producing a range `gate pulse that is shiftable in time with respect to an interrogation pulse, a range motor, a ranging unit -for controlling the timing of said range gate, gear drive means having two different gear ratios either one of which may be selected to couple said motor to said ranging unit, a single servo channel which has its output coupled to said motor for driving it, Inode switching means for automatically switching the DME into an automatic trackin-range mode in response to received reply pulses passing through said range gate and including means for applying a range enror signal to the input of said servo channel and including means for selecting a certain lone of said gear ratios vfor slow drive of the ranging unit, mode switching means for automatically switching the DME from the track-in-range mode to a memory mode in response to loss of reply pulses with the DME still in slow servo drive of the ranging unit, mode switching means for au-tomatically switching the DME from the memory mode to a search-in-range mode upon failure of reply pulses to return quickly enough to return the DME to the track-in-range mode and including means for applying a range search signal to the input of said servo channel and including means for selecting the other of said `gear ratios for fast drive of said ranging unit, mode switching means or automatically switching the DME fnom the search-in-range mode to an acquisition mode in response to the receipt of reply pulses that ipass through said range gate and including means for 'applying a range error signal to the input of said servo channel and including means for selecting said certain one of said gear ratios for slow drive of the ranging unit, said DME switching to the track-in-range mode at the end of the acquisition mode period if a suicient number of received reply pulses pass through the range gate during the acquisition mode period, and an automatic control circuit comprising means responsive to output pulses from said decoder for reducing the strength of said range sea-rch signal in response to fading or loss Iof said decoder output pulses and thereby reducing the speed during said search-in-range mode.

9. Distance measuring equipment that is to be airborne and is to intenrogate a selected ground transponder station which is of the type that transmits pulses at all times whether being interrogated or not, said equipment comprising a transmitter, means for causing said transmitter to transmit interrogation pulses to said selected ground station, receiving means for receiving from said ground station its transmitted pulses including reply pulses in response to said interrogation, means for producing a range gate which may be varied in time with respect to said interrogation pulses, search means -for causing said lrange gate to search-in-range until it is coincident in time with said reply pulses, means responsive to said coincidence for causing said equipment to track automatically in range, an automatic search velocity control circuit to which output pulses from said receiving means are applied, a voltage threshold circuit, means for integrating said applied pulses to obtain a control voltage which is applied to said threshold circuit, and means for holding the speed Iof said search-in-range at a comparatively low speed in response to said control voltage being below the threshold voltage of said threshold circuit and for increasing the speed of said searchin-range in response to said control voltage exceeding the threshold voltage iof said threshold circuit.

No references cited.

CHESTER L. JUSTUS, Primary Examiner. 

1. PULSE RADAR EQUIPMENT COMPRISING A TRANSMITTER, MEANS FOR CAUSING SAID TRANSMITTER TO TRANSMIT PULSES, RECEIVING MEANS FOR RECEIVING RETURN PULSES IN RESPONSE TO SAID TRANSMISSION, MEANS FOR PRODUCING A RANGE GATE WHICH MAY BE VARIED IN TIME WITH RESPECT TO SAID TRANSMITTED PULSES, SEARCH MEANS FOR CAUSING SAID RANGE GATE TO SEARCH RAPIDLY IN RANGE UNTIL IT IS COINCIDENCE IN TIME WITH SAID RETURN PULSES, MEANS RESPONSIVE TO SAID COINCIDENCE FOR CAUSING SAID EQUIPMENT TO TRACK AUTOMATICALLY IN RANGE, AN AUTOMATIC SEARCH VELOCITY CONTROL CIRCUIT TO WHICH OUTPUT PULSES FROM SAID RECEIVING MEANS ARE APPLIED, SAID CONTROL CIRCUIT COMPRISING MEANS RESPONSIVE TO SAID APPLIED PULSES FOR REDUCING THE SPEED OF SAID SEARCHING-RANGE IN RESPONSE TO FADING OR LOSS OF SAID APPLIED PULSES. 